KR101479809B1 - Method For Improving Performance Of Heating And Cooling System And Heating and Cooling System Using The Method - Google Patents

Abstract

The present invention relates to a heating and cooling apparatus such as a building and a vinyl house which can dramatically improve the performance of a heating and cooling facility by adequately adjusting the air movement speed through the improvement of the air conditioner installed or installed in a large building, And more particularly, to a method and apparatus for improving performance of the apparatus.
Further, the present invention relates to a technology applicable to an air conditioner and a radiator which are operated independently.
According to the present invention, there is provided a method for controlling an air conditioning system, comprising: a step of improving the cooling / heating equipment so that the discharge velocity V of the air at the discharge port satisfies the following formula (1).
0.45 * H? V? 0.75 * H - (1)
However, when the V value calculated by the above formula (1) exceeds a maximum value of 3 m / s and a minimum value of 1.8 m / s, the maximum or minimum value is adopted.
In the cooling / heating apparatus with improved performance according to the present invention, since heat exchange between air and cold / hot water is sufficiently performed in the heat exchanger, air adjusted to a desired temperature is supplied into the room, .

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heating /

The present invention relates to a method for improving the performance of a cooling / heating facility installed in a building or a vinyl house, a cooling / heating facility newly installed, and a cooling / heating facility using the method.

More particularly, the present invention relates to a building and a vinyl house, which can dramatically improve the performance of the air-conditioning and heating system by appropriately adjusting the air movement speed through the improvement of the air- The present invention relates to a method for improving performance of a facility and a facility apparatus thereof.

Further, the present invention relates to a technology applicable to an air conditioner and a radiator which are operated independently.

Large buildings are equipped with heating and cooling facilities for heating and cooling the buildings. Fig. 1 is a schematic view of a heating / cooling facility installed in a large building at present. As shown in FIG. 1, the heating / cooling equipment installed in a large building includes a cold / hot water heater 100, an air conditioner 200, and a duct 300.

The air conditioner 200 includes a heat exchanger 210 for exchanging heat between cold water or hot water produced by the cold / hot water generator, and an air blower 210 for transferring the air, (220).

The duct 300 is a tube for transferring the temperature-adjusted air from the air conditioner 200 to the room. A discharge port 310 is formed at the end of the duct, and the discharge port 310 is generally provided on the ceiling or wall of the room Respectively.

The operation of the cooling / heating equipment installed in the building produces cold water or hot water in the cold / hot water generator 100 and sends it to the heat exchanger 210. In the heat exchanger 210, cold water or hot water flowing inside, The temperature of the air is adjusted to a desired temperature by the heat exchange of the air to be transferred and the air whose temperature is adjusted in the air conditioner 200 is supplied to the room 400 through the discharge port 310, .

Generally, in order to maintain a suitable temperature for controlling the indoor space to a desired temperature by the heating / cooling facility, the amount of heat required for cooling and heating must be supplied. The relationship between the holding temperature of the indoor space and the amount of heat supplied is considerably complicated. For example, the volume of the indoor space, the height of the ceiling, the arrangement and number of the air outlet, the air temperature and speed at the outlet, the indoor humidity, the indoor furniture, And the interrelation with the elements to be considered such as the frequency of opening and closing of the heat exchanger, etc. can not be calculated by the formula. The convection phenomenon due to the temperature difference and density difference of the air, the heat conduction phenomenon of the furniture and the radiation heat of the heating element are more complicated . As a result, it is difficult to accurately calculate the correlation between the supplied calorific value and the room temperature in consideration of the above requirements. Therefore, the capacity of each facility is calculated from the general design conditions, and the facility that is closest to the capacity of the heating / The capacity value of the battery is selected.

Therefore, it is common that the capacity of the building is higher than that of the appropriate heating and heating facilities, and the capacity is installed in excess of 20 ~ 30% considering the peak of mid-summer and winter.

In addition, the heating and cooling facilities installed in the present building are designed so that the heat exchanged air is conveyed at a high speed in order to quickly adjust the indoor temperature to a desired temperature, thereby allowing time for the air to sufficiently exchange heat in the heat exchanger The air that has passed through the heat exchanger is supplied to the room without reaching the most suitable temperature for heating and cooling.

Air supply air discharged from the discharge port 310 of the duct 300 can not be uniformly distributed throughout the room 400 due to the above-mentioned cause, and the efficiency of cooling and heating during the circulation of the air is decreased, And environmental pollution such as carbon dioxide emission.

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to improve the operating method and equipment of the over-capacity heating / cooling equipment installed in the building and the newly installed over- To supply air with sufficient heat exchange in the heat exchanger. In addition, the present invention is also applied to the heating of a plastic greenhouse requiring heating, thereby reducing the air movement speed by the blower to sufficiently heat the air, thereby improving the heating efficiency, thereby reducing energy consumption and environmental pollution.

The method and apparatus for increasing the efficiency of the heating and cooling system according to the present invention are derived from the process of finding the most efficient heating and cooling operation system while practically operating the designed heating and cooling system without consideration of various requirements in the heating and cooling system. It is applied to existing and new heating and cooling equipments to improve existing heating and cooling equipments and applied to newly installed cold confinement equipments.

The technical idea of the present invention is to lower the air movement speed in the air conditioner and the discharge port so that the heat is sufficiently exchanged in the heat exchanger so that the air is supplied to a lower temperature during cooling and the air is supplied at a higher temperature during heating, ≪ / RTI >

Generally, in order to obtain the desired room temperature by operating the cooling system in the summer, the room temperature of 24 ° C can be obtained within 2 hours after the cooling system is started. This means that the circulating cold water of the cold / hot water or the turbo- It is possible to obtain cold water of about 7 ° C only for a period of time of about 30 minutes to 2 hours, and it is possible to obtain the desired room temperature by exchanging heat in the heat exchanger for circulating cold water for about 30 minutes. At this time, in the heat exchanger of the air conditioner, the speed of air discharge by the blower is fast. As a result, the temperature of the air to be supplied is not sufficiently lowered and the temperature of the air to be supplied is not sufficiently lowered and the temperature of the circulating cold water is also rapidly increased by the air speed As a result, the temperature of the outlet is kept at 14 ° C to 15 ° C, the temperature of circulating cold water is increased to about 12 ° C, and the cold / hot water heater continues to operate, but the operation is repeated As a result, the indoor cooling efficiency is reduced.

However, by reducing the blower speed in the air conditioner and sufficiently exchanging the heat-exchanged air, the air is slowly supplied to the discharge outlet by lowering the supply air temperature by 1.5 to 2 ° C lower than the supply air temperature in the heat exchanger during the normal air- And the indoor air circulation through the heat exchanger continuously increased the efficiency of the heat exchange. As a result, the operation time of the water cooler was reduced to 20 ~ 30% of the total energy consumption.

That is, since the heat is sufficiently exchanged in the heat exchanger, even if the cold water starts to be supplied for about 30 minutes without dropping the cold water temperature of the cold water heater to about 7 ° C, the cold water temperature is maintained at about 12 ° C and the supply temperature can be maintained at 12 ° C to 13 ° C So that it can be supplied at a temperature 1.5 to 2 ° C lower than the conventional method. At this time, the circulating cold water of the cold / hot water machine also reduces the air moving speed in the heat exchanger and relatively less heat is taken to save energy, and the operation time of the cold / hot water machine can be reduced by such a chain reaction and the indoor cooling effect is increased.

This phenomenon is applied when heating the supply air temperature in the same way as when cooling air.

In order to reduce the discharge rate of air and sufficiently exchange heat in the heat exchanger as described above, the following method is preferable for achieving the cooling and heating effect as in the present invention.

The method and apparatus for improving the performance of a heating / cooling system installed in a building according to the present invention is characterized in that the height H (m) from the floor to the ceiling and the discharge velocity V (m / sec) And further improving the cooling / heating equipment so that the supply air temperature is further lowered during cooling and the supply air temperature is increased during heating.

0.45 * H? V? 0.75 * H - (1)

It is preferable that the maximum value or the minimum value is adopted when the V value calculated by the formula (1) exceeds a maximum value of 3 m / s and a minimum value of 1.8 m / s. If the outlet is far from or close to the installation conditions, the air velocity can be increased or decreased to within 10%.

The above equation (1) is the most preferred embodiment for adjusting the air speed of the discharge port in the normally operating cooling and heating facility. The discharge speed at the discharge port of the air depends on the building structure and the air conditioner capacity, The air discharge speed of the discharge port can be determined by adjusting the speed of the blower so that heat can be properly exchanged in the heat exchanger. At this time, the air discharge speed of the discharge port may be increased to a value or a maximum value determined in accordance with the condition.

According to another preferred feature of the present invention, the supply air temperature discharged from the discharge opening is lower than the reference temperature of the conventional cooling / heating equipment, which is normally designed and operated, by at least 1.5 degrees during cooling and at least 1.5 degrees higher during heating .

According to another preferred aspect of the present invention, the temperature of the air exchanged in the heat exchanger and supplied to the discharge port by the blower is equal to or less than the cold / hot water temperature, .

According to another preferred feature of the present invention, it is preferable that the discharge speed (V) of the air at the discharge port is kept constant during the operation of the cooling / heating equipment.

According to a preferred feature of the present invention, the improvement of the cooling / heating facility is characterized in that heat exchange in the heat exchanger is sufficiently performed by adjusting the rotation speed of the blower associated with the air speed of the discharge port to lower the discharge speed in the blower.

According to another preferred feature of the present invention, the blower is composed of a motor and a fan mechanically connected to the motor, and the motor shaft is replaced with a pulley having a diameter satisfying the following formula, or the rotation speed of the blower is adjusted To a desired speed.

According to another preferred aspect of the present invention, the blower is installed at the front end and the rear end of the heat exchanger, and the air discharge speed at the discharge port side and the temperature of the discharged air are adjusted according to the regulation of the rotational speed of the blower .

According to another preferred feature of the present invention, the present invention is applied to a heating system of a greenhouse for cultivating horticultural crops and the like, and the heating efficiency is increased to save energy.

According to another preferred feature of the present invention, energy is directly applied to heating facilities supplied to individual air conditioners and apartments, thereby saving energy.

In the cooling / heating system with improved performance according to the present invention, heat exchange between air and cold / hot water is sufficiently performed in the heat exchanger, and air adjusted to a temperature that is efficient for cooling and heating is supplied. Thereby saving energy.

This performance improvement can be achieved not only by a relatively simple method such as adjusting the rotation speed by the inverter connected to the blower-side motor or replacing the blower motor, but also by adjusting the speed by simply replacing the blower motor-side pulley Therefore, the construction period is considerably short and the investment cost of the facility is small, but the facility improvement effect of the heating and heating facilities is remarkable. Therefore, it is expected to shorten the investment payback period, save energy and reduce carbon emissions.

In addition, by reducing the rotating speed of the blower fan, the electricity consumption is reduced, the usable life of the device is increased, and there is almost no noise in the room.

The present invention maximizes the performance improvement effect by providing a method of deriving an optimum supply air temperature and a moving speed by operating not only the moving speed of air but also the driving speed.

When the present invention is applied, the amount of carbon dioxide emission is reduced as much as the energy saving amount, and the profit of the carbon emission right is expected.

FIG. 1 is a schematic view of a heating /
2 is a schematic view of a blower installed in a current building,
Fig. 3 is a schematic view of a motor-side Polyman replaced blower according to the present invention.
4 is a configuration diagram of a heating system for a greenhouse according to the present invention,
5 is a layout diagram of a duct in a greenhouse according to the present invention.

The inventor of the present invention has conducted research on a method and an apparatus for improving the performance of a heating / cooling system installed or installed in a building, and thus the present invention has been accomplished. In the present invention, the most important part of the present invention is to improve the performance of the heating / cooling equipment to be installed in a building or a vinyl house, and to minimize the investment cost and the construction period, the heating / Minimizing the modification of the system.

Accordingly, in the present invention, in order to minimize the investment cost and the construction period required for the improvement of performance, it is necessary to change the capacity of the cold / hot water heater and the heat exchanger, or to eliminate a large investment cost such as replacing the duct or the discharge hole with a different diameter desirable.

In view of the above, the inventor analyzed the problems of the air conditioner installed in the building and the vinyl house, and the air conditioner installed in the presently installed air conditioner is designed to rapidly control the temperature of the room, It has been found that the air passed through the heat exchanger is supplied to the room in a state in which it is not suitable for cooling and heating and has not reached an effective temperature without sufficient time for sufficient heat exchange in the heat exchanger.

The present invention improves the performance of the air conditioner by providing the air moving speed at which the air can sufficiently stay in the heat exchanger so that the air passing through the heat exchanger is suitable for cooling and heating and can reach an efficient temperature.

For this purpose, in the present invention, the feed rate of the air is controlled to provide a time margin enough for heat exchange in the heat exchanger 210 to occur. In the present invention, the conveyance speed of the air is controlled on the basis of the conveyance speed of the air at the ejection opening 310 provided in the room, which is the easiest to measure the conveyance speed of the air, and the rotating speed of the blower in the air conditioner associated therewith.

In the heating / cooling system installed in the present building, the discharge speed of the air at the discharge port 310 is 5 to 16 m / s. In the most preferred embodiment of the present invention, The discharging speed V of the air at the discharging port 310 is reduced to such an extent that the following equation (1) can be satisfied.

0.45 * H? V? 0.75 * H - (1)

Here, H is the height from the floor to the ceiling of the room where the discharge port is installed, and the calculated unit of V is m / s.

For example, if the height of the room is 4 m, it is most preferable to operate the air conditioning system so that the discharge speed (V) of the air at the discharge port may be 1.8 m / s to 3 m / s.

However, when the V value calculated by the above formula (1) exceeds the maximum value of 3 m / s and the minimum value of 1.8 m / s, it is most preferable to operate by adopting the maximum value or the minimum value. If the flow rate is less than 1.8 m / s, the flow of air is too small to control the temperature of the room. If the flow rate is more than 3 m / s, heat exchange is not sufficiently performed in the heat exchanger.

The above equation (1) is the most preferred embodiment for adjusting the air speed of the discharge port in the universally operating cooling / heating equipment, and the discharge speed at the discharge port of the air is linked to the blower installed at the heat exchanger side of the air conditioner, The air discharge speed of the discharge port can be determined based on the speed of the blower to such an extent that heat can be appropriately exchanged to increase the heating and cooling efficiency. Therefore, depending on the structure of the building, the capacity of the heating and cooling facility, and the like, the air discharge speed of the discharge port can be increased to the speed and the maximum value by the above formula.

In the present invention, it is preferable that the discharge speed V of the air at the discharge port 310 is kept constant from the initial operation to the stop. That is, by keeping the moving speed of the air constant in an optimum state, sufficient heat exchange is always performed in the heat exchanger, so that the air adjusted to the desired temperature can be continuously supplied to the room.

In the present invention, the rotational speed of the blower 220 installed in the air conditioner 200 is adjusted in order to suitably adjust the air discharge speed at the discharge port 310 according to the present invention.

In the present invention, the rotational speed of the blower 220 installed in the air conditioner 200 is adjusted to adjust the discharge speed of the air at the discharge port 310 to the discharge speed calculated by the equation (1).

That is, the air speed of the air is controlled by adjusting the rotational speed of the air blower 220

The method of controlling the rotational speed in the blower 220 is as follows: 1) the replacement of the blower motor 2) the replacement of one or more of the fan side or the motor side poly 3) the installation and adjustment of the inverter controlling the blower motor .

A method of replacing the blower motor is to replace the blower motor so that the blower of the heating and cooling equipment installed in the current building can maintain the air discharge speed calculated by the above method. Even in this case, the electricity consumption and the fuel consumption are reduced, the usable time of the equipment is increased, and there is no noise.

Next, a method of minimizing the investment cost is to change the rotation speed of the blower to a desired speed by replacing the pulleys whose diameters are different from each other on the rotation axis of the motor and the fan. In this case, either one of the rotation shaft of the motor and the fan may be replaced, or both of them may be exchanged. Preferably, the pulley is replaced with a pulley having a small diameter capable of controlling the rotation speed on the blower motor side.

FIG. 2 is a schematic view of a blower installed in a current building, and FIG. 3 is a schematic view of a blower in which a motor-side poly according to the present invention is replaced by a small diameter fly.

2, the blower includes a motor 224, a motor side pulley 226, a fan 223, a fan side pulley 225, a belt 227 connecting the motor side pulley 226 and the fan side pulley 225 In the embodiment of FIG. 3, the motor-side pulley 230 is replaced with a smaller diameter. In this case, since the motor is not replaced, there is no change in the amount of electricity used, but the advantage is that the fuel consumption is reduced even though the investment cost is low.

Further, the above-described methods may be used in combination. Specifically, a method of replacing the pulley while replacing the motor may also be used. For example, when the motor capacity and the pulley diameter are reduced by half, TαP / N (where T: Torque, P: Number of motor poles, N: Number of rotations) Reducing air volume by 1/2 reduces motor capacity by 1/2, satisfying the torque required for blower start, reducing electricity consumption and fuel consumption.

For example, if the frequency of the inverter output is controlled, the speed of the motor of the blower is proportional to the square of the frequency, and the power is proportional to the square of the frequency. If you reduce it to 30Hz, the rotation speed can be reduced to 1/4, and the power can be reduced to 1 / 8th. If the speed of the blower is controlled in this way, the air conveying speed in the heat exchanger is controlled according to the blower speed, and the supplied electric power is also controlled.

However, since the control method of the inverter generates harmonics in the operation process and may affect the control of other devices, it is preferable to operate the inverter in consideration of this.

Considering this fact, the inverter output frequency is adjusted up to 50Hz in the air-conditioning system equipped with the inverter, but we have not seen a case where it is reduced for the purpose of improving the cooling and heating efficiency.

The reason why the amount of energy used in the present invention is reduced can be explained by the following equation.

* Calculation of the amount of energy converted into energy

Gas volume (CMH) * Specific gravity Kg / m3 * Conversion temperature difference = Thermal capacity

Air volume m ³ / sec * Specific heat of air * Specific gravity * Conversion temperature difference = kcal 1kwh = 760kcal

That is, when the gas volume (air volume) is reduced, the energy consumed is also saved in proportion to the air volume.

When the number of revolutions of the blower is reduced, the amount of air delivered by the blower decreases in proportion to the number of revolutions, and the velocity (intensity) of the conveyed air decreases in proportion to the square of the number of revolutions. This also reduces the amount of energy consumed by the heat exchanger. However, the heat exchange is sufficiently performed so that the temperature of the cold / hot water circulated from the cold / hot water machine or the freezer / boiler is lowered when the air is cooled by the blower through the heat exchanger. As a result, the speed of the air discharged during the cooling and heating is reduced, but the temperature of the air supplied from the heat exchanger is sufficiently lowered or increased, thereby increasing the cooling and heating efficiency. In other words, if the air speed is reduced and the air with sufficient heat exchange is supplied, the desired cooling and heating air supply temperature is obtained even if the operation time of the cold / hot water supply unit or the freezing turbo / boiler is reduced, and the cooling / Lt; / RTI >

On the other hand, the blower in the heating / cooling equipment installed in the present building can be installed at the front end and the rear end of the heat exchanger, respectively. 1), reference numeral 221 denotes a blower installed at the rear end of the heat exchanger 210, and reference numeral 222 denotes a blower installed at the front end of the heat exchanger 210. [ Here, if there is no window in the room and a separate smoking facility is not provided, the blower 222 installed at the front end of the heat exchanger should be used as a smoke exhaust system in case of an emergency. In this case, It can not be applied to the blower 222 installed at the front end. Of course, in this case, it may be applied to the blower installed at the front end of the heat exchanger. In the case of a fire, the blower 221 installed at the rear end of the heat exchanger is automatically stopped and the blower 222 installed at the front end of the heat exchanger serves as a flue gas outlet. If the number of revolutions of the blower installed at the front end of the heat exchanger is reduced, Because it does not perform its role properly.

The experimental procedure and the effect of the improvement of the heating and cooling equipment according to the present invention will be described.

The present inventor has experimented with the same large building over two years. That is, in the first year, the air conditioner installed in the current building was installed and the inverter was installed. In the second year, the optimum air moving speed was derived according to the present invention, The air conditioner was operated at the optimum air moving speed by controlling the blower motor rotational speed. In the first year, the air discharge rate at the outlet of the heating / cooling system installed in the current building was 8 ~ 16m / s. Since the ceiling height of the building is 3.6m, the optimal air discharge rate is calculated by equation (1) As a result, the air moving speed of the discharge port was 2.7 m / s, and the air speed at the discharge port was actually adjusted to 2.7 m / s to operate the air conditioner.

As a result, it was possible to reduce the operation time of the cold / hot water system from 2 hours to 30 minutes before going to work, and the temperature of the cold water circulated after 30 minutes in the state of supplying air from the air conditioner becomes 12 degrees. 13 degrees. The room temperature was easily reached at 24 degrees and the heat exchanger did not occur in the air conditioner while maintaining 24 degrees, so the cold / hot water heater was operated without further depriving of the calories. When the indoor temperature exceeds 24 degrees, the air supplied from the air conditioner is heat-exchanged with the cold water through the heat exchanger, so that the supply air temperature is lowered, and the cooling air is supplied at a temperature lower by 1.5 degrees than the normal supply air temperature before the change. This operation was repeated to save energy.

As a result of the test run, the electricity consumption and the fuel consumption are shown in Table 1 below.

Comparison of electricity and fuel usage (inverter installation operation; proper wind speed fixed operation) division Electricity (Kwh) Fuel (gas, m3) First year The second year increase First year The second year increase In May 597,388 559,913 -37, 475 9,399 3,781 -5,618 June 715,870 671,360 -44,510 22,867 20,973 -1,894 In July 765,746 694,596 -44,682 44,682 31,075 -13,607 August 836,684 807,527 -54,980 54,980 41,011 -13,969

As shown in Table 1, it can be seen that the usage of electricity and fuel is reduced by improving the operation method of the heating / cooling equipment installed in the present building.

Electricity saving is pure electric power supplied to the blower according to the speed control of the blower, and since the cooling method is gas type, the gas saving in cooling is mainly performed.

The present invention is characterized in that energy is efficiently used by optimizing the moving speed of air supplied during heat exchange in an air conditioner so that sufficient heat can be exchanged in a heat exchanger. By accomplishing this object by a simple method, Which is a characteristic feature.

In addition, the present invention can be equally applied to a case where a cooling / heating air-conditioning facility is already completed, and a cooling / heating air-conditioning facility is newly installed in a building to be newly constructed.

Also, in order to control the rotation speed of the blower motor for controlling the moving speed of the air in the air conditioner, the cooling / heating efficiency of the building can be improved by using the method of the present invention for a newly installed inverter as well as an existing inverter.

Meanwhile, the present invention can be applied to an air conditioner and a heating system which are operated independently in an office, a restaurant, a home or the like. For example, when the air discharging speed is ineffectively calculated and is unnecessarily large, So that the effect of heat exchange can be sufficiently achieved. At this time, the air discharge speed is determined according to the method defined in the present invention.

The present invention is also applicable to a vinyl house heating system.

In order to cultivate flowers, vegetables, trees and horticultural crops in the plastic house, it is necessary to heat at a certain temperature necessary for cultivation. The air discharge speed of the heating equipment installed in the plastic house reaches 20m / sec on the average, The heating efficiency is largely reduced by being supplied to the outlet of the duct in the vinyl house at a temperature of about 40 ° C without being sufficiently exchanged.

If the speed of the air discharged from the heat exchanger is reduced according to the method of the present invention, warm air of 50 ° C or more, which has sufficiently exchanged heat in the heat exchanger, is discharged into the duct, so that the temperature of the air in the greenhouse can be efficiently raised. In order to adjust the moving speed of the air to be discharged, an inverter may be installed in the blower or a motor may be replaced and a pulley may be used to achieve power saving and the object of the present invention.

In a specific embodiment,

4 is a configuration diagram of a heating system in a greenhouse according to the present invention.

As shown in FIG. 4, the vinyl house heating system of the present invention includes a boiler 100 for producing hot water required for heating, an air conditioner (not shown) for exchanging heat between the hot water and the air sucked into the plastic house, 200 and a duct 300 for transferring conditioned air to the room.

The boiler 100 generates hot water for heating required for growth of crops in the greenhouse.

The air conditioner 200 includes a heat exchanger 210 for heat exchange between hot water and air produced by the boiler, and an air blower 220 for transferring the air.

The heat exchanger 210 exchanges heat between the boiler 100 and the air sucked from the inside of the greenhouse.

In the rear surface of the blower 220, air is sucked from the greenhouse room 400 and is heat-exchanged in the heat exchanger 210 in the air conditioner 200 and discharged to the duct 300 on the front surface of the blower 220 .

Therefore, the air conveyance speed is controlled by the rotation output of the blower 220 so that the heat exchanger 210 has a sufficient time margin to generate the air of the set temperature.

The duct 300 is connected to the end of the air conditioner 200 and can withstand the resistance of the air to transfer the temperature-controlled air from the heat exchanger 210 to the greenhouse 400. However, And is formed of a material such as vinyl which can easily form a plurality of discharge ports 310 at a desired position, and is composed of two pipes including a plurality of discharge ports 310.

5 is a layout diagram of a duct in a greenhouse according to the present invention.

As shown in FIG. 5, the two ducts 300 are divided into four equal lengths of the vinyl house left and right lengths, and the two ducts 300 are located at the first divided length from the left and the first divided length from the right. It is preferable to arrange the duct 300 at a position where the position of the duct 300 is one half of the height of the vinyl house so that the temperature-adjusted air can be uniformly distributed throughout the vinyl house .

Unlike a building, the ventilation speed of a vinyl house duct is low, the insulation effect is low, and a large space is heated by a single duct. Therefore, the air discharge speed is designed to be about 10 to 20 m / sec faster than the building.

Therefore, it is most preferable to set the air discharge speed condition twice as much as the heating temperature of the building.

That is, 0.9 * H? V? 1.5 * H. (H: height from floor to ceiling [m])

The blower speed is adjusted so that the air discharge speed is the maximum or the minimum as defined herein when the air discharge speed is out of a maximum of 6 m / s and a minimum of 1.8 m / s.

However, the air discharge rate can be determined as the air discharge rate of the discharge port obtained by adjusting the speed of the blower so that heat exchange can be properly performed in the heat exchanger. At this time, the air discharge speed of the discharge port may be smaller than the lower limit value defined above or larger than the upper limit value.

Another advantageous feature of the present vinyl house heating system is that the temperature of the circulating hot water and the air to be discharged are substantially equal to each other or in the range of 10 to 15 degrees or less.

The discharge ports 310 are formed on upper, lower, right and left sides of the vinyl duct 300 so as to be easily removable by the perforated lines at predetermined intervals. When the temperature of the room is required to be controlled, So that the position and number of the discharge port can be adjusted on the vinyl duct.

As a result of the vinyl house heating test by the method of the present invention, the electricity consumption amount and the fuel consumption amount were compared as follows.

In order to increase the outdoor temperature 19 ℃ to 23 ℃, the frequency of the inverter supplied to the blower was set to 60Hz. As a result, the moving speed of the air was measured at 21m / sec. In order to raise the temperature from 19 ℃ to 23 ℃, Min.

The speed of the air was reduced to 3.5m / sec as the frequency of the inverter was reduced to 25Hz. As a result, the speed of the air was reduced to 3.5m / sec. ℃, and the residual heat remaining in the boiler was maintained for 5 minutes after the boiler shut down. Electricity consumption of the blower also decreased to about 14 minutes.

In the above-mentioned method and apparatus for heating a plastic house, the heating concept of the above-mentioned building is applied equally. However, there is only difference in application temperature due to difference of structural difference and heating capacity.

Although the present invention has been described with reference to the preferred embodiments of the present invention, the present invention is not limited to the cooling / heating equipment of the existing building, the new building, the air conditioner and the heating unit, and the heating unit of the plastic house.

The present invention may be embodied in various forms without departing from the scope of the appended claims and the accompanying drawings, and this also falls within the scope of the present invention.

100: Heating / cooling unit
200: air conditioner
210: heat exchanger
220: blower
221: blower installed at the rear end of the heat exchanger
222: blower installed at the front end of the heat exchanger
223; blower fan
224;
230: Motor side pulley
300: Duct
310:
400: Indoor

Claims (17)

A cold / hot water machine for producing cold water or hot water required for cooling and heating;
An air conditioner including a heat exchanger for exchanging heat between cold water or hot water produced in the cold / hot water heater and an air blower for transferring the heat exchanged air; And
The air conditioning system of claim 1, wherein the air supply duct has a discharge port for discharging the air that has been heat-exchanged in the air conditioner. (1) below so that the air discharge speed (V) at the discharge port can be supplied at a minimum of 1.5 ° C or lower at the time of heating and at least 1.5 ° C or higher at the time of heating, Wherein the speed of the blower is kept constant at the reduced blower rotational speed while the blower is operating.

0.45 * H? V? 0.75 * H - (1)
Where H is the height from the floor of the room to the ceiling where the outlet is installed, m is the unit, and V is the unit of m / s.
However, if the V value calculated by the above formula (1) exceeds a maximum of 3 m / s and a minimum of 1.8 m / s, the maximum or minimum value is adopted.
delete delete delete The method according to claim 1,
Wherein the blower is composed of a motor and a fan mechanically connected to the motor, and the rotational speed of the blower is adjusted by replacing the motor with a pulley whose diameter is different from that of the fan.
delete A cold / hot water machine for producing cold water or hot water required for cooling and heating;
An air conditioner including a heat exchanger for exchanging heat between cold water or hot water produced in the cold / hot water heater and an air blower for transferring the heat exchanged air; And
And a duct for air transfer formed at a distal end of the duct to discharge the heat-exchanged air to the room,
The air discharge speed V at the discharge port is lower than the reference supply air temperature, which is higher than the reference air supply temperature and is higher than the reference supply air temperature by at least 1.5 deg. Wherein the blower rotational speed is reduced within a range satisfying the formula (1), and is kept constant at the reduced blower rotational speed during the operation of the blower, wherein the blower comprises a motor and a fan mechanically connected thereto Wherein the rotating speed of the blower is adjusted by replacing the motor with a pulley having a diameter different from that of the rotation shaft of the fan.

0.45 * H? V? 0.75 * H - (1)
Where H is the height from the floor of the room to the ceiling where the outlet is installed, m is the unit, and V is the unit of m / s.
However, if the V value calculated by the above formula (1) exceeds a maximum of 3 m / s and a minimum of 1.8 m / s, the maximum or minimum value is adopted.
delete delete delete delete delete delete delete In the vinyl house heating system in which the capacity of the heating equipment is more than the normal capacity,
A water heater producing hot water required for heating;
An air conditioner including a heat exchanger for exchanging heat between hot water and air produced in the water heater and an air blower for transferring the heat exchanged air; And
And a duct in which a discharge port for discharging the heat-exchanged air from the air conditioner into the greenhouse is formed,
(V) at the discharge port satisfies the following formula (1) so that the air can be supplied at a temperature at least 10 ° C higher than the reference supply air temperature, The blower rotation speed is reduced and the reduced blower rotation speed is kept constant during the operation of the blower. The reduction in the rotation speed of the blower is achieved by controlling the rotation speed of the blower by connecting the inverter to the blower motor Features of the greenhouse heating system.
0.9 * H? V? 1.5 * H - (1)
Where H is the height from the floor of the room to the ceiling where the outlet is installed, m is the unit, and V is the unit of m / s.
However, if the V value calculated by the above formula (1) exceeds a maximum value of 6 m / s and a minimum value of 1.8 m / s, the maximum or minimum value is adopted.
delete 16. The method of claim 15,
Wherein the duct is formed with a plurality of discharge openings which can be easily removed by perforations at regular intervals in the upper, lower, left, and right sides of the duct.

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